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Modelling continuous exposures - fractional polynomials

Willi Sauerbrei Institut of Medical Biometry and Informatics University Medical Center Freiburg, Germany. Patrick Royston MRC Clinical Trials Unit, London, UK. Modelling continuous exposures - fractional polynomials. Overview. Observational Studies.

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Modelling continuous exposures - fractional polynomials

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  1. Willi SauerbreiInstitut of Medical Biometry and Informatics University Medical Center Freiburg, Germany Patrick Royston MRC Clinical Trials Unit, London, UK Modelling continuous exposures - fractional polynomials

  2. Overview

  3. Observational Studies Several variables, mix of continuous and (ordered) categorical variables Different situations: • prediction • explanation • confounders only Explanation is the main interest here: • Identify variables with (strong) influence on the outcome • Determine functional form (roughly) for continuous variables The issues are very similar in different types of regression models (linear regression model, GLM, survival models ...) Use subject-matter knowledge for modelling ... ... but for some variables, data-driven choice inevitable

  4. Regression models X=(X1, ...,Xp) covariate, prognostic factors g(x)= ß1 X1 + ß2 X2 +...+ ßp Xp (assuming effects are linear) normal errors (linear) regression model  Y normally distributed E (Y|X) = ß0 + g(X) Var (Y|X) = σ2I logistic regression model Y binary Logit P (Y|X) = ln survival times  T survival time (partly censored) Incorporation of covariates g(X) (g(X))

  5. Central issue To select or not to select (full model)? Which variables to include? How to model continuous variables?

  6. Continuous variables – The problem “Quantifying epidemiologic risk factors using non-parametric regression: model selection remains the greatest challenge” Rosenberg PS et al, Statistics in Medicine 2003; 22:3369-3381 Discussion of issues in (univariate) modelling with splines Trivial nowadays to fit almost any model To choose a good model is much harder

  7. Building multivariable regression models Before dealing with the functional form, the ‚easier‘ problem of model selection: variable selection assuming that the effect of each continuous variable is linear

  8. Multivariable models – methods for variable selection Full model • variance inflation in the case of multicollinearity Stepwise procedures prespecified (in, out) and actual significance level? • forward selection (FS) • stepwise selection (StS) • backward elimination (BE) All subset selection which criteria? • Cp Mallows = (SSE / ) - n + p 2 • AIC Akaike Information Criterion = n ln (SSE / n) + p 2 • BIC Bayes Information Criterion = n ln (SSE / n) + p ln(n) fit penalty Combining selection with Shrinkage Bayes variable selection Recommendations??? Central issue: MORE OR LESS COMPLEX MODELS?

  9. Backward elimination is a sensible approach • Significance level can be chosen • Reduces overfitting Of course required • Checks • Sensitivity analysis • Stability analysis

  10. Continuous variables – what functional form? Traditional approaches a)   Linear function - may be inadequate functional form - misspecification of functional form may lead to wrong conclusions b)   ‘best‘ ‘standard‘ transformation c)    Step function (categorial data) - Loss of information - How many cutpoints? - Which cutpoints? - Bias introduced by outcome-dependent choice

  11. StatMed 2006, 25:127-141

  12. Fractional polynomial models • Describe for one covariate, X • Fractional polynomial of degree m for X with powers p1, … , pm is given byFPm(X) = 1Xp1 + … + mXpm • Powers p1,…, pm are taken from a special set{2,  1,  0.5, 0, 0.5, 1, 2, 3} • Usually m = 1 or m = 2 is sufficient for a good fit • Repeated powers (p1=p2) 1Xp1 + 2Xp1log X • 8 FP1, 36 FP2 models

  13. Examples of FP2 curves- varying powers

  14. Examples of FP2 curves- single power, different coefficients

  15. Our philosophy of function selection • Prefer simple (linear) model • Use more complex (non-linear) FP1 or FP2 model if indicated by the data • Contrasts to more local regression modelling • Already starts with a complex model

  16. Example 1: Prognostic factorsGBSG-study in node-positive breast cancer 299 events for recurrence-free survival time (RFS) in 686 patients with complete data 7 prognostic factors, of which 5 are continuous

  17. FP analysis for the effect of age

  18. Function selection procedure (FSP)Effect of age at 5% level? χ2 df p-value Any effect? Best FP2 versus null 17.61 4 0.0015 Linear function suitable? Best FP2 versus linear 17.03 3 0.0007 FP1 sufficient? Best FP2 vs. best FP1 11.20 2 0.0037

  19. Many predictors – MFP With many continuous predictors selection of best FP for each becomes more difficult  MFP algorithm as a standardized way to variable and function selection (usually binary and categorical variables are also available) MFP algorithm combines backward elimination with FP function selection procedures

  20. Continuous factorsDifferent results with different analysesAge as prognostic factor in breast cancer (adjusted) P-value 0.9 0.2 0.001

  21. Results similar?Nodes as prognostic factor in breast cancer (adjusted) P-value 0.001 0.001 0.001

  22. Example 2: Risk factors • Whitehall 1 • 17,370 male Civil Servants aged 40-64 years, 1670 (9.7%) died • Measurements include: age, cigarette smoking, BP, cholesterol, height, weight, job grade • Outcomes of interest: all-cause mortality at 10 years  logistic regression

  23. Whitehall 1 Systolic blood pressure Deviance difference in comparison to a straight line for FP(1) and FP(2) models

  24. Similar fit of several functions

  25. Presentation of models for continuous covariates • The function + 95% CI gives the whole story • Functions for important covariates should always be plotted • In epidemiology, sometimes useful to give a more conventional table of results in categories • This can be done from the fitted function

  26. Whitehall 1 Systolic blood pressure  Odds ratio from final FP(2) model LogOR= 2.92 – 5.43X-2 –14.30* X –2 log X Presented in categories

  27. Whitehall 1MFP analysis No variables were eliminated by the MFP algorithm Assuming a linear function weight is eliminated by backward elimination

  28. InteractionsMotivation – I Detecting predictive factors (interaction with treatment) • Don’t investigate effects in separate subgroups! • Investigation of treatment/covariate interaction requires statistical tests • Care is needed to avoid over-interpretation • Distinguish two cases: • Hypothesis generation: searching several interactions • Specific predefined hypothesis

  29. Motivation - II Continuous by continuous interactions • usually linear by linear product term • not sensible if main effect is non-linear • mismodelling the main effect may introduce spurious interactions

  30. (Searching for) treatment – covariate interaction • Most popular approach • Treatment effect in separate subgroups • Has several problems (Assman et al 2000) • Test of treatment/covariate interaction required • For `binary`covariate standard test for interaction available • Continuous covariate • Often categorized into two groups • loss of information, loss of power • which cutpoint?

  31. Interactions with treatment - MFPI • Have one continuous factor X of interest • Useother prognostic factors to build an adjustment model, e.g. by MFP Interaction part – with or without adjustment • Find best FP2 transformation of X with same powers in each treatment group • LRT of equality of reg coefficients • Test against main effects model(no interaction) based on 2 with 2df • Interpretation predefined hypothesis or hypothesis searching?

  32. RCT: Metastatic renal carcinoma Comparison of MPA with interferon N = 347, 322 Death

  33. Overall: Interferon is better (p<0.01) • Is the treatment effect similar in all patients? Sensible questions? • Yes, from our point of view • Ten factors available for the investigation of treatment – covariate interactions  Interaction with WCC is significant

  34. MFPI Treatment effect function for WCC Only a result of complex (mis-)modelling?

  35. Does the MFPI model agree with the data?Check proposed trend Treatment effect in subgroups defined by WCC HR (Interferon to MPA; adjusted values similar) overall: 0.75 (0.60 – 0.93) I : 0.53 (0.34 – 0.83) II : 0.69 (0.44 – 1.07) III : 0.89 (0.57 – 1.37) IV : 1.32 (0.85 –2.05)

  36. Continuous by continuous interactionsMFPIgen • Have Z1, Z2 continuous and X confounders • Apply MFP to X, Z1 and Z2, forcing Z1 and Z2 into the model. • FP functions f1(Z1) and f2(Z2) are selected for Z1 and Z2 • Often f1(Z1) and/or f2(Z2) are linear • Add term f1(Z1)* f2(Z2) to the model chosen and use LRT for test of interaction • Check (graphically) interactions for artefacts • Check all pairs of continuous variables for an interaction • Use forward stepwise if more than one interaction remains • Low significance level for interactions

  37. Interactions – continuous by continuousWhitehall 1 Consider only age and weight Main effects: age – linear weight – FP2 (-1,3) Interaction? Include age*weight-1 + age*weight3 into the model LRT: χ2 = 5.27 (2df, p = 0.07)  no (strong) interaction

  38. Erroneously assume that the effect of weight is linear Interaction? Include age*weight into the model LRT: χ2 = 8.74 (1df, p = 0.003)  intercation appears higly significant

  39. Interactions: checking the model • Model check: categorize age in (equal sized) groups (e.g. 4 groups) • Compute running line smooth of the binary outcome on weight in each group • Plot results for each group

  40. Whitehall 1: check of ageweight interaction– 4 subgroups for age

  41. Interpreting the plot • Running line smooth are roughly parallel across age groups  no (strong) interactions • Erroneously assume that the effect of weight is linear  estimated slopes of weight in age-groups indicate strong qualitative interaction between age und weight

  42. Whitehall 1: 7 variables – any interactions? P-values for two-way interactions from MFPIgen *FP transformations  cholage highly significant, but needs checking

  43. Software sources MFP • Most comprehensive implementation is in Stata • Command mfp is part since Stata 8 (now Stata 10) • Versions for SAS and R are available • SAS www.imbi.uni-freiburg.de/biom/mfp • R version available on CRAN archive • mfp package • Extensions to investigate interactions • So far only in Stata

  44. Concluding comments – MFP • FPs use full information - in contrast to a priori categorisation • FPs search within flexible class of functions (FP1 and FP2 - 44 models) • MFP is a well-defined multivariate model-building strategy – combines search for transformations with BE • Important that model reflects medical knowledge, e.g. monotonic / asymptotic functional forms

  45. Towards recommendations for model-building by selection of variables and functional forms for continuous predictors under several assumptions Sauerbrei et al. SiM 2007

  46. Interactions • Interactions are often ignored by analysts • Continuous  categorical has been studied in FP context because clinically very important • Continuous  continuous is more complex • Interaction with time important for long-term FU survival data

  47. MFP extensions • MFPI – treatment/covariate interactions • MFPIgen – interaction between two continuous variables • MFPT – time-varying effects in survival data

  48. Summary Getting the big picture right is more important than optimising aspects and ignoring others • strong predictors • strong non-linearity • strong interactions • strong non-PH in survival model

  49. References Harrell FE jr. (2001): Regression Modeling Strategies. Springer. Royston P, Altman DG. (1994): Regression using fractional polynomials of continuous covariates: parsimonious parametric modelling (with discussion). Applied Statistics, 43:429-467. Royston P, Ambler G, Sauerbrei W. (1999): The use of fractional polynomials to model continuous risk variables in epidemiology. International Journal of Epidemiology, 28:964-974. Royston P, Sauerbrei W. (2004): A new approach to modelling interactions between treatment and continuous covariates in clinical trials by using fractional polynomials. Statistics in Medicine, 23:2509-2525. Royston P, Sauerbrei W. (2007): Improving the robustness of fractional polynomial models by preliminary covariate transformation: a pragmatic approach. Computational Statistics and Data Analysis, 51:4240-4253. Royston P, Sauerbrei W (2008): Multivariable Model-Building - A pragmatic approach to regression analysis based on fractional polynomials for continuous variables. Wiley. Royston P, Sauerbrei W (2008): Two techniques for investigating interactions between treatment and continuous covariates in clinical trials. Stata Journal, to appear. Sauerbrei W. (1999): The use of resampling methods to simplify regression models in medical statistics. Applied Statistics, 48, 313-329. Sauerbrei W, Meier-Hirmer C, Benner A, Royston P. (2006): Multivariable regression model building by using fractional polynomials: Description of SAS, STATA and R programs. Computational Statistics & Data Analysis, 50:3464-3485. Sauerbrei W, Royston P. (1999): Building multivariable prognostic and diagnostic models: transformation of the predictors by using fractional polynomials. Journal of the Royal Statistical Society A, 162:71-94. Sauerbrei W, Royston P, Binder H (2007): Selection of important variables and determination of functional form for continuous predictors in multivariable model building. Statistics in Medicine, 26:5512-28. Sauerbrei W, Royston P, Zapien K. (2007): Detecting an interaction between treatment and a continuous covariate: a comparison of two approaches. Computational Statistics and Data Analysis, 51:4054-4063.

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